Power generating apparatus, power generating system, and wireless electric power transmission apparatus with impedance matching

1. A power generator comprising: a power generating section configured to output DC energy; an oscillating section configured to convert the DC energy into RF energy with a frequency f 0 ; a power-transmitting antenna that is a series resonant circuit having a resonant frequency fT that is set to be substantially equal to the frequency f 0 , and configured to transmit the RF energy; a power-receiving antenna that is a parallel resonant circuit having a resonant frequency fR that is set to be substantially equal to the frequency f 0 , and configured to receives at least a part of the RF energy that has been transmitted by the power-transmitting antenna; a rectifying section configured to convert the RF energy that has been received by the power-receiving antenna into DC energy; an impedance matching section for oscillating section that is arranged between the oscillating section and the power-transmitting antenna, and configured to match an input impedance of the power-transmitting antenna to an output impedance of the oscillating section; and a transmitting-end control section configured to match an input impedance of the oscillating section to an output impedance of the power generating section by changing the input impedance of the oscillating section in accordance with a variation in the output impedance of the power generating section, and configured to match an input impedance of the impedance matching section for oscillating section to the output impedance of the oscillating section by changing the input impedance of the impedance matching section for oscillating section in accordance with the variation in the output impedance of the power generating section.

2. The power generator of claim 1 , further comprising a measuring section that measures the output current and output voltage of the power generating section, wherein the output impedance value of the power generating section is detected based on the output current and output voltage that have been measured by the measuring section.

3. The power generator of claim 1 , wherein when the output impedance of the power generating section varies, the transmitting-end control section changes the input impedance of the power-transmitting antenna accordingly, thereby matching the input impedance of the power-transmitting antenna to the output impedance of the impedance matching section for oscillating section.

4. The power generator of claim 1 , wherein the oscillating section includes multiple oscillators having respective predefined input impedance ranges, and wherein the transmitting-end control section chooses one of the oscillators according to the output impedance value of the power generating section and makes current flow through the oscillator chosen, thereby changing the input impedance of the oscillating section.

5. The power generator of claim 1 , wherein the impedance matching section for oscillating section includes multiple matching circuits having respective predefined input impedance ranges, and wherein the transmitting-end control section chooses one of the matching circuits according to the output impedance value of the oscillating section and makes current flow through the matching circuit chosen, thereby changing the input impedance of the impedance matching section for oscillating section.

6. The power generator of claim 1 , wherein the impedance matching section for oscillating section includes multiple capacitors and multiple inductors, and wherein the transmitting-end control section chooses a combination including one of the capacitors and one of the inductors according to the output impedance value of the oscillating section, and makes current flow through the capacitor and the inductor that are included in the chosen combination, thereby changing the input impedance of the impedance matching section for oscillating section.

7. The power generator of claim 3 , wherein the power-transmitting antenna includes multiple inductors that are connected together in series and multiple capacitors that are connected in series to the inductors, and wherein the transmitting-end control section chooses at least one of the inductors and at least one of the capacitors according to the output impedance value of the power generating section, and makes current flow through the at least one inductor chosen and the at least one capacitor chosen, thereby changing the input impedance of the power-transmitting antenna.

8. The power generator of claim 3 , wherein the power-transmitting antenna includes: at least two inductors, which have mutually different inductances and which are arranged in parallel with each other; and another inductor, which is arranged in the vicinity of the at least two inductors, and wherein the transmitting-end control section chooses one of the at least two inductors according to the output impedance value of the power generating section, and makes current flow through the chosen inductor, thereby changing the input impedance of the power-transmitting antenna.

9. The power generator of claim 3 , wherein the power-transmitting antenna includes an inductor, multiple capacitors that are connected in series to the inductor, and a movable portion with a metallic or magnetic body, and wherein the transmitting-end control section changes the distance between the inductor and the movable portion, and chooses at least one of the capacitors, according to the output impedance value of the power generating section, and makes current flow through the at least one capacitor chosen, thereby changing the input impedance of the power-transmitting antenna.

10. The power generator of claim 3 , wherein the power-transmitting antenna includes multiple resonators, which have mutually different input impedances, and wherein the transmitting-end control section chooses one of the resonators according to the output impedance value of the power generating section, and makes current flow through the resonator chosen, thereby changing the input impedance of the power-transmitting antenna.

11. The power generator of claim 1 , further comprising: an impedance matching section for rectifying section, which is arranged between the power-receiving antenna and the rectifying section in order to match the input impedance of the rectifying section to the output impedance of the power-receiving antenna; and a receiving-end control section that matches the input impedance of the impedance matching section for rectifying section to the output impedance of the power-receiving antenna by changing the input impedance of the impedance matching section for rectifying section in accordance with a variation in the output impedance of the power generating section.

12. The power generator of claim 11 , wherein when the output impedance of the power generating section varies, the receiving-end control section changes the input impedance of the rectifying section accordingly, thereby matching the input impedance of the rectifying section to the output impedance of the impedance matching section for rectifying section.

13. The power generator of claim 11 , wherein when the output impedance of the power generating section varies, the receiving-end control section changes the output impedance of the power-receiving antenna accordingly, thereby matching the output impedance of the power-receiving antenna to the input impedance of the impedance matching section for rectifying section.

14. The power generator of claim 11 , further comprising an environmental condition sensing section that measures an environmental parameter of the power generating section, wherein when the environmental parameter that has been measured by the environmental condition sensing section varies, the receiving-end control section changes the input impedance of the impedance matching section for rectifying section accordingly, thereby matching the input impedance of the impedance matching section for rectifying section to the output impedance of the power-receiving antenna.

15. The power generator of claim 14 , wherein when the environmental parameter that has been measured by the environmental condition sensing section varies, the receiving-end control section changes the input impedance of the rectifying section accordingly, thereby matching the input impedance of the rectifying section to the output impedance of the impedance matching section for rectifying section.

16. The power generator of claim 14 , wherein when the environmental parameter that has been measured by the environmental condition sensing section varies, the receiving-end control section changes the output impedance of the power-receiving antenna accordingly, thereby matching the output impedance of the power-receiving antenna to the input impedance of the impedance matching section for rectifying section.

17. The power generator of claim 11 , wherein the impedance matching section for rectifying section includes multiple matching circuits, which have had their input impedance ranges defined in advance, and wherein the receiving-end control section chooses one of those matching circuits and makes current flow through the matching circuit chosen, thereby changing the input impedance of the impedance matching section for rectifying section.

18. The power generator of claim 11 , wherein the impedance matching section for rectifying section includes multiple capacitors and multiple inductors, and wherein the receiving-end control section chooses a combination including one of the capacitors and one of the inductors and makes current flow through the capacitor and the inductor that are included in the chosen combination, thereby changing the input impedance of the impedance matching section for rectifying section.

19. The power generator of claim 11 , wherein the rectifying section includes multiple rectifiers, which have had their input impedance ranges defined in advance, and wherein the receiving-end control section chooses one of those rectifiers and makes current flow through the rectifier chosen, thereby changing the input impedance of the rectifying section.

20. The power generator of claim 11 , wherein the power-receiving antenna includes multiple inductors that are connected together in series and multiple capacitors that are arranged in parallel with the inductors, and wherein the receiving-end control section chooses at least one of the inductors and at least one of the capacitors and makes current flow through the at least one inductor chosen and the at least one capacitor chosen, thereby changing the output impedance of the power-receiving antenna.

21. The power generator of claim 11 , wherein the power-receiving antenna includes: at least two inductors, which have mutually different inductances and which are arranged in parallel with each other; and another inductor, which is arranged in the vicinity of the at least two inductors, and wherein the receiving-end control section chooses one of the at least two inductors and makes current flow through the chosen inductor, thereby changing the output impedance of the power-receiving antenna.

22. The power generator of claim 11 , wherein the power-receiving antenna includes an inductor, multiple capacitors that are arranged in parallel with the inductor, and a movable portion with a metallic or magnetic body, and wherein the receiving-end control section changes the distance between the inductor and the movable portion, chooses at least one of the capacitors and makes current flow through the at least one capacitor chosen, thereby changing the output impedance of the power-receiving antenna.

23. The power generator of claim 11 , wherein the power-receiving antenna includes multiple resonators, which have mutually different input impedances, and wherein the receiving-end control section chooses one of the resonators and makes current flow through the resonator chosen, thereby changing the output impedance of the power-receiving antenna.

24. The power generator of claim 14 , wherein the environmental parameter includes a parameter representing the irradiance of the sunlight received at the power generating section.

25. The power generator of claim 14 , wherein the environmental parameter includes a parameter representing the temperature of the power generating section.

26. The power generator of claim 14 , wherein the environmental parameter measured by the environmental condition sensing section is transmitted wirelessly to the receiving-end control section.

27. The power generator of claim 1 , wherein the power generating section is a solar power generating section.

28. The power generator of claim 27 , wherein the solar power generating section generates electric power by using crystalline silicon.

29. The power generator of claim 27 , wherein the solar power generating section and the power-transmitting antenna are arranged outside of a building and the power-receiving antenna is arranged inside of the building.

30. The power generator of claim 27 , wherein the solar power generating section, the power-transmitting antenna, and the power-receiving antenna are arranged outside of a building, and wherein the power-transmitting and power-receiving antennas are arranged so as to face each other at least partially.

31. The power generator of claim 1 , wherein when the voltage step up ratio of the oscillating section is Voc, the inductance of the power-transmitting antenna is L 1 , the inductance of the power-receiving antenna is L 2 , and a coupling coefficient between the power-transmitting and power-receiving antennas is k, (L 2 /L 1 )≧4(k/Voc) 2 is satisfied.

32. The power generator of claim 31 , wherein the rectifying section has an output voltage of 200 V to 300 V.

33. A power generation system comprising a number of power generators, wherein at least two of the power generators have their output terminals arranged in parallel with each other, and wherein the at least two power generators are as defined by claim 1 .

34. A wireless power transmission system comprising: an oscillating section configured to convert DC energy into RF energy with a frequency f 0 ; a power-transmitting antenna that is a series resonant circuit having a resonant frequency fT that is set to be substantially equal to the frequency f 0 , and configured to transmits the RF energy; a power-receiving antenna that is a parallel resonant circuit having a resonant frequency fR that is set to be substantially equal to the frequency f 0 , and configured to receives at least a part of the RF energy that has been transmitted by the power-transmitting antenna; a rectifying section configured to convert the RF energy that has been received by the power-receiving antenna into DC energy; an impedance matching section for oscillating section that is arranged between the oscillating section and the power-transmitting antenna, and configured to match an input impedance of the power-transmitting antenna to an output impedance of the oscillating section; and a transmitting-end control section configured to match an input impedance of the oscillating section to an output impedance of a power generating section by changing the input impedance of the oscillating section in accordance with a variation in the output impedance of the power generating section, and configured to match an input impedance of the impedance matching section for oscillating section to the output impedance of the oscillating section by changing the input impedance of the impedance matching section for oscillating section in accordance with the variation in the output impedance of the power generating section.